A control system for resonant inertial actuators estimates operating parameters of the resonant inertial actuators based on voltage and current feedback and dynamically limits selected parameters to maintain the safe, efficient, and cost effective operation of the resonant inertial actuators. Resistance within the electrical drives for the resonant inertial actuators is estimated from the voltage and current feedback and in conjunction with the modeling of the resonant inertial actuators other operating parameters are calculated or otherwise estimated. Having regard for the responsiveness of the resonant inertial actuators to changes in command signals, the command signals are adjusted to dynamically limit the estimated parameters.
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1. A method of dynamically limiting an operating parameter of a resonant inertial actuator operating with a vibrating structure, the method comprising:
driving the resonant inertial actuator at a near resonant frequency of the resonant inertial actuator for counteracting vibrations in the structure;
intermittently driving the resonant inertial actuator at an off-resonance frequency for separate intervals of time;
monitoring a current and a voltage through the resonant inertial actuator over at least portions of the separate intervals of time;
calculating values of the operating parameter of the resonant inertial actuator based on the monitored current and voltage within the separate intervals of time; and
reducing a demanded force of the resonant inertial actuator in response to calculated values of the operating parameter crossing a threshold value.
2. The method of
3. The method of
4. The method of
the operating parameter is an actuator displacement operating parameter; and
reducing the demanded force includes reducing the demanded force in response to calculated values of the actuator displacement operating parameter crossing the threshold value.
5. The method of
calculating values of the actuator force operating parameter based on the values of the actuator displacement operating parameter; and
reducing the demanded force of the resonant inertial actuator in response to calculated values of the actuator force operating parameter crossing an actuator force threshold value.
6. The method of
7. The method of
transforming the monitored current and voltage in a time domain into a complex current value and a complex voltage value in a frequency domain; and
averaging the complex current and voltage values over at least a portion of the time domain.
8. The method of
9. The method of
10. The method of
11. The method of
comparing the calculated value of the operating parameter against the threshold value, wherein the threshold value relates to a desired range of operation for the resonant inertial actuator; and
limiting a command output of the resonant inertial actuator to maintain the value of the operating parameter within the desired range.
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This patent application claims the benefit of and is a divisional application of U.S. application Ser. No. 13/983,463, filed Aug. 2, 2013, which claims the benefit of, and incorporates by reference, international application PCT/US2012/023802 filed on Feb. 3, 2012 and U.S. Provisional Application No. 61/439,710 filed on Feb. 4, 2011, all of which are incorporated herein by reference in their entireties.
The invention relates to aircraft vibration control systems and linear motor controls and in particular to electronic controls for resonant inertial actuators of vibration-cancelling force generators for such purposes of regulating electrical and mechanical outputs.
Resonant inertial actuators of vibration-cancelling force generators, such as those used for at least partially cancelling unwanted rotary wing aircraft vibrations, include electronic control systems that regulate electrical drive currents for driving the resonant inertial actuators about a natural resonant frequency. The rotary wing aircraft vibration cancelling electronic control systems include a command input for receiving a command signal and a power amplifier for providing the electrical drive current to the resonant inertial actuator. A feedback system from the resonant inertial actuator to the electronic control system adjusts the electrical drive current based on outputs of the resonant inertial actuator.
The vibration-cancelling force generators are attached to the aircraft machine structure that is subject to the unwanted vibrations. Resonant inertial actuators have a frame for attachment to the machine structure and an electromagnetically driven sprung mass supported by the frame. The sprung mass, which includes an inertial mass connected to the base frame through a resilient coupling, such as flexure plates, is electromagnetically driven by modulating an oriented electromagnetic field so that the sprung mass is oscillated at the natural resonance frequency. The resonance frequency of the sprung mass corresponds to the frequency at which the machine structure is subject to unwanted vibration, and the phase of the sprung mass oscillation is offset with respect to the phase of the unwanted vibration to produce destructive interference.
The command signal can be a variable analog input voltage received by the command input as an instruction to provide a scaled electrical drive current to the resonant inertial actuator. The feedback system, which also connects the resonant inertial actuator to the electronic control system, can monitor both a feedback current through the resonant inertial actuator and a feedback voltage across the inertial actuator. Based on the two feedbacks, the electronic control system can limit the inertial actuator current and voltage to respective maximum values.
When driving the resonant inertial actuator with drive current, significant changes in the force response of the inertial actuator are known to accompany frequency sweeps through the frequency of the inertial actuator's natural resonance. On the other hand, voltage control is known to have a much flatter response in both magnitude and phase through the natural resonance frequency. Near resonance, a weak current loop has been used, which has some voltage-like performance near resonance.
Known resonant inertial actuators have strict design limits for such parameters as voltage, current, force, stroke, power, and temperature. To assure safe and efficient operation within these design limits, resonant inertial actuators are generally designed with considerable “overhead” in their mechanical and electrical design. The overhead, which involves additional design features or scaling to larger sizes or capacities, generally result in heavier and more expensive inertial actuators and actuator controls.
In embodiments the invention includes management and limiting of vibration within vibrating machine structures of rotary wing aircraft machines, and includes among its preferred embodiments methods for dynamically limiting one or more operating parameters of rotary wing aircraft vibration control system resonant inertial actuators operating within the vibrating structures for maintaining safe, efficient, and cost effective operation of the resonant inertial actuators. In addition, responsiveness of the resonant inertial actuators to command signals is addressed or otherwise accommodated for achieving the desired control over the operation of the resonant inertial actuators. Resonant inertial actuator parameters such as voltage, current, power, stroke, force, and temperature are monitored and dynamically limited. By maintaining operation of the resonant inertial actuators within design limits, such as set by these parameters, the inertial actuators can be sized and otherwise designed more closely to the design limits and can be operated with improved efficiency and reliability.
Resistance within the electrical drives for the resonant inertial actuators can be estimated from voltage and current feedback from the resonant inertial actuators, and in conjunction with modeling of the resonant inertial actuators, other operating parameters can be calculated or otherwise estimated. Responsiveness of the resonant inertial actuators to changes in command signals can be optimized both for achieving the desired output of the inertial actuators and for dynamically limiting the monitored parameters of the inertial actuators.
Voltage control with current limiting can be used to improve the flatness of the force response. A dead zone current loop can be used to generate error values associated with sensed current values beyond a determined limit. A command signal to the inertial actuator can be progressively reduced in response to the accumulation of the error values. Additional filtering can also be used to further improve the flatness of the response.
Digital signal processing (DSP) provides for shape filtering, online estimating of resistance and temperature, and calculating displacement and force. Quadrature amplitude demodulation can be used to measure the magnitudes of voltage, current, displacement, temperature, force, and power of the inertial actuators.
In embodiments the invention features a method of limiting vibration in a rotary wing aircraft having a vibrating structure and a vibration control system for dynamically limiting an operating parameter of a resonant inertial actuator operating within the vibrating structure. The resonant inertial actuator is driven at a near resonant frequency of the resonant inertial actuator for counteracting vibrations in the vibrating structure of the rotary wing aircraft. In addition, the resonant inertial actuator is intermittently driven at an off-resonance frequency for separate intervals of time. Performance of an electric circuit for powering the resonant inertial actuator is monitored over at least portions of the separate intervals of time. Values of the operating parameter of the resonant inertial actuator are calculated based on the monitored performance of the electric circuit within the separate time intervals. A demanded force of the resonant inertial actuator is reduced in response to calculated values of the resonant inertial actuator operating parameter crossing a threshold value.
For example, resistance values of the electric circuit can be estimated from the monitored performance and these resistance values can be incorporated into the calculation of the values of the resonant inertial actuator operating parameter. The operating parameter can be actuator displacement and the demanded force can be reduced in response to calculated values of the actuator displacement crossing the resonant inertial actuator threshold value. Values of a second operating parameter in the form of an actuator force parameter can be calculated from the values of the displacement parameter. The demanded force of the resonant inertial actuator can be reduced in response to calculated values of the force parameter crossing a resonant inertial actuator threshold value. Other resonant inertial actuator operating parameters that can be monitored include the temperature of the inertial actuator, which can be limited by the reduction in the demanded force, and actuator power, which can be used as another threshold value for reducing the demanded force.
In embodiments the invention features a method of operating a vibration control system of a rotary wing aircraft for counteracting vibrations in a vibrating structure of the aircraft. Current and voltage through a resonant inertial actuator are monitored over at least a portion of an interval of time. Vibration frequency of the vibrating structure of the rotary wing aircraft is also monitored. The monitored current and voltage in a time domain is transformed in reference to the vibration frequency in quadrature into complex current and voltage values in a frequency domain over at least a portion of the time interval. The complex values for current and voltage are incorporated into a calculation of a value of an operating parameter of the resonant inertial actuator. The calculated value of the operating parameter is compared to a threshold relating to a desired range of operation for the resonant inertial actuator. The command output of the resonant inertial actuator is limited to maintain the value of the operating parameter within the desired range.
In embodiments the resonant inertial actuator operating parameter is preferably at least one of actuator temperature, actuator displacement, actuator force, and actuator power and has a calculated value based at least in part on the averaged complex values for current and voltage.
In embodiments the interval of time can be one of a plurality of separate time intervals. The resonant inertial actuator can be intermittently driven at an off-resonance frequency that departs from the monitored frequency for the separate time intervals. The complex values for current and voltage can be incorporated into a calculation which includes estimating resistance values through the resonant inertial actuator as a real part of impedance. The estimated resistance values can be incorporated in turn into the calculation of the operating parameter. The command output can be limited by limiting at least one of current and voltage for driving the inertial actuator.
In an embodiment the invention includes a machine, the machine includes a resonant inertial actuator controller and a resonant inertial actuator, the resonant inertial actuator has a resonant frequency, the resonant inertial actuator controller electromagnetically drives the resonant inertial actuator at a near resonant frequency, with the near resonant frequency proximate the resonant frequency, the resonant inertial actuator controller intermittently drives the resonant inertial actuator at an off-resonance frequency for separate intervals of time, with the off-resonance frequency distal from the resonant frequency, with the resonant inertial actuator controller monitoring a current and a voltage through the resonant inertial actuator over at least portions of the separate intervals of time, and with the controller calculating an operating parameter value of the resonant inertial actuator based on the monitored current and the monitored voltage within the separate time intervals wherein the controller reduces the demanded force of the resonant inertial actuator in response to the calculated operating parameter value crossing a threshold value.
It is to be understood that both the foregoing general description and the following detailed description are exemplary of the invention, and are intended to provide an overview or framework for understanding the nature and character of the invention as it is claimed. The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate various embodiments of the invention, and together with the description serve to explain the principals and operation of the invention.
Additional features and advantages of the invention will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from that description or recognized by practicing the invention as described herein, including the detailed description which follows, the claims, as well as the appended drawings. Reference will now be made in detail to the present preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. In preferred embodiments the invention provides improvements to the control of linear motors, particularly resonant inertial actuators such as disclosed in U.S. Pat. No. 7,686,246 of Badre-Alam et al. and International Patent Application Publication No. WO 2010/053933 of Badre-Alam et al.; both of which being hereby incorporated by reference.
The parallel arrangement 5 is cantilevered from the support base 3, with the flexure parts 7, 11 and the voice coil motor part 9 extending outward from the support base 3 in the manner of a cantilever. The ends 8, 12 of the flexure parts 7, 11, respectively, which are coupled to the support base 3, are the fixed or supported ends of the flexure parts 7, 11. The ends 10, 14 of the flexure parts 7, 11, respectively, which are unattached to the support base 3, are the moving or unsupported ends of the flexure parts 7, 11. The unsupported ends 10, 14 of the flexure parts 7, 11, respectively, are coupled to a magnet part 13 of the voice coil motor part 9.
In addition to the magnet part 13, the voice coil motor 9 also includes an interacting driving coil part (15 in
In the spring-mass actuator system, the cantilevered flexure-supported magnet part 13 and its associated cantilevered flexure-supported moving mass members represent a sprung moving mass, and the flexure parts 7, 11 represent a spring. The magnet part 13 creates a magnetic field. When alternating current is supplied to the physically grounded non-sprung, non-moving coil part 15, the coil part 15 interacts with the magnetic field created by the sprung moving mass magnet part 13 to generate an electromagnetic driving force that vibrates the cantilevered flexure-supported sprung moving mass magnet part 13. The sprung moving mass magnet part 13 moves in an arc as it is electromagnetically driven (i.e., moves up and down along a vertical direction in relation to the support base 3 (and the grounded coil 15) and in and out relative to the support base 3 at the same time to trace an arc). If the frequency of the alternating current supplied to the coil part (15 in
Referring to
Still referring to
In
In
Also, in
Returning to
Returning to
Each flexure 52 is in the form of a beam plate. The flexures 52 can be made of a non-elastomeric material, which may be metallic, non-metallic, or composite. Preferably, the flexures 52 are made of a composite or non-metallic material. In one embodiment, a composite material suitable for the flexures is comprised of reinforcing fibers in a polymer resin. In another embodiment, a composite material suitable for the flexures is comprised of a carbon-fiber reinforced composite. In another embodiment, the carbon-fiber reinforced composite is comprised of carbon fibers in a cured polymer matrix. In another embodiment, the carbon-reinforced fiber composite is comprised of carbon fibers in a cured epoxy matrix. The shims 54 could be made of metal or elastomer, with elastomer being preferred. In a preferred embodiment the elastomeric material for the shims is post-vulcanized rubber. The shims 54 in a preferred embodiment are bonded to the flexures 54 proximate their ends and the clamps 58, with the shims inhibiting a fretting of the flexures as they move with the stroke of the voice coil motor. Preferably the bonded elastomeric shims 54 are provided to inhibit a fretting of the flexures 54.
The distal ends of the flexure stack 50 are inserted into apertures 56 in flexure clamps 58 and held in the apertures 56, e.g., by friction. The flexure clamps 58 have a double row bolt arrangement 60 (i.e., two rows of bolts, with the rows positioned on opposite sides of the clamps), and with this arrangement, the flexure stack 50 can be firmly attached to the bracket (49 in
Returning to
In an embodiment the invention includes the aircraft machine 61, the machine includes resonant inertial actuator controller 65 and resonant inertial actuator 1, the resonant inertial actuator has a resonant frequency, the resonant inertial actuator controller electromagnetically drives the resonant inertial actuator at a near resonant frequency, with the near resonant frequency proximate the resonant frequency, the resonant inertial actuator controller intermittently drives the resonant inertial actuator at an off-resonance frequency for separate intervals of time, with the off-resonance frequency distal from the resonant frequency, with the resonant inertial actuator controller monitoring a current and a voltage through the resonant inertial actuator over at least portions of the separate intervals of time, and with the controller calculating an operating parameter value of the resonant inertial actuator based on the monitored current and the monitored voltage within the separate time intervals wherein the controller reduces the demanded force of the resonant inertial actuator in response to the calculated operating parameter value crossing a threshold value. Preferably the resonant inertial actuator 1 is a cantilevered resonant inertial actuator, preferably with a sprung moving mass magnet part moving in an arc. Preferably the cantilevered resonant inertial actuator has adjacent composite flexures 52 with bonded elastomer end fret inhibiting shims 54 between the adjacent composite flexures, preferably with the composite flexures providing for the sprung moving mass magnet part moving in the arc. Preferably the resonant inertial actuator operating parameter is at least one resonant inertial actuator operating parameter selected from the resonant inertial actuator operating parameter group including an actuator temperature, an actuator displacement, an actuator force, and an actuator power. Preferably the controller electromagnetically drives the resonant inertial actuator at the near resonant frequency with a demanded force power, and the controller drives the resonant inertial actuator at the off-resonance frequency with a non-resonant frequency power less than the demanded force power.
Preferred embodiments of the invention are directed to control systems and the control of resonant inertial actuators such as by voltage control systems with current limiting. Preferred embodiments of the invention include control systems with improved flatness of both a magnitude and a phase response, improving a base input rejection, and using a dead zone current loop to limit current exceeding a given threshold. Preferably the control systems provide for monitoring and dynamic limiting of operating parameters of resonant inertial actuators such as resonant inertial actuator operating parameters selected from the resonant inertial actuator operating parameter group including voltage, current, power, stroke, force, and temperature.
Preferably such improvements are implemented via Digital Signal Processing (DSP), Field Programmable Gate Array (FPGA) motor control, and filtering. The improvements to Digital Signal Processing (DSP) preferably include (a) shape filtering to provide frequency dependent gain, (b) online estimates of resistance and temperature, (c) calculations of displacement and force, (d) quadrature amplitude demodulation to monitor voltage, current, power, displacement, and force, along with calculated root mean squared (rms) power, and (e) dynamic limiting of voltage, current, power, displacement, force, and temperature.
In contrast to control systems in earlier examples of resonant inertial actuators, embodiments of the invention are preferably based on voltage rather that current control. Although voltage control is not subject to significant changes in the force response near the natural resonance frequency of the resonant inertial actuators, some further flattening of the force response over an intended operating range of oscillation frequencies is still possible as illustrated by the magnitude and phase plots vs. frequency of
where ωnom is the nominal frequency and ω is the drive frequency.
Real time up to date online estimates of resistance can be taken by operating the resonant inertial actuator off resonance and processing values of the feedback current i and voltage v through the resonant inertial actuator. Indications of the stroke, force, and temperature of the resonant inertial actuator can be derived from estimates of resistance within the drive circuit (largely a coil) of the resonant inertial actuator. The resistance within the drive circuit of the resonant inertial actuator is expected to be affected by temperature increases accompanying the heating of the electromagnetic coil and, thus, is best estimated online. The resistance can be derived from the real part of the impedance.
An estimate of the resistance can be carried out by driving the resonant inertial actuator through a negligible stroke at non-resonant frequency so that the back (counter) electromotive force (bemf) portion of the impedance is negligible. For example, as shown in
The quadrature amplitude demodulation and block averaging of the complex current I and complex voltage V is explained by the schematic diagram of
The temperature T of the coil (i.e., the main portion of the drive circuit) can be estimated from changes in coil resistance. A relationship between resistance and temperature is presented below:
where Tref is the ambient (room) temperature, Rref is the resistance measured at the ambient temperature Tref, R is a more recent (e.g., the latest) resistance estimate, and λ is a temperature coefficient of resistance, such as λ=0.00393 for copper wire in the coil.
Preferably, the resistance “R” is periodically estimated (e.g., every 30 seconds) for monitoring changes in the estimated temperature T. A temperature limiting scheme is implemented for protecting the actuator coil, in which the demanded force is limited until the temperature is reduced below the limit. Any reduction in the force output of the actuator is preferably carried out at a slow enough rate for the temperature T to respond to the reduction in force and power.
Estimating the resistance R also allows for open and short circuit detection. If the resistance estimate R is outside of a normal resistance range for an extended period of time, then an actuator fault protection can be triggered by turning the affected channel off.
For calculating displacement and force, an electrical description of the motor can be derived from Kirchhoff's voltage law as follows:
where, R is the resistance, L is the inductance, Vbemf is the back electromotive force of the motor.
Equation 25 can be related to the velocity of the resonant actuator through the constitutive law for back emf as follows:
Vbemf=Kt{dot over (x)} 26
Substituting Equation 26 into 25, and expressing the equation in the Laplace domain, the following equation results:
V−sXKt−IR−sIL=0 27
where “s” is a numerical derivative symbol.
Referring to
where “1/s” is a numerical integration function, “α” is a measurable motor constant, and “L” is inductance.
Based on the calculated displacement X and using Newton's second law, a relationship for actuator force Fa can be calculated as follows:
ΣF=s2mX=Fa 29
Assuming a simple harmonic motion of the resonant inertial actuator, Equation 29 can be rewritten as follows:
Fa=s2mX=(jω)2mX=−mω2X 210
Equations 28 and 210 can be used to estimate actuator displacement X and force Fa. These equations are advantageous because non-linear parameters such as stiffness and mechanical damping fall out of the equations. The remaining parameters tend to be relatively constant except for resistance R, which can be estimated online as described above. A schematic diagram presented in
To obtain magnitudes of voltage Vmag, current Imag, root mean squared power Prms, displacement Xmag, and force Fmag, quadrature amplitude demodulation can be used as shown in the schematic diagram of
Once having acquired their online values, limits can be set or otherwise controlled for the operating parameters of Voltage V, Current I, Power Prms, Displacement X, Force Fa, and Temperature T. The plots of
A preferred implementation of a Field Programmable Gate Array (FPGA) motor control is schematically depicted in
An implementation of the interpolation filter, as shown in
A duty cycle command is generally directly proportional to the voltage command signal if the voltage rail from a power supply unit is constant. However, under some loading conditions the voltage rail can have about a ripple voltage at the N/rev drive frequency. If unaccounted for, this ripple would distort the desired drive voltage. To avoid this distortion, the duty cycle command can be normalized by the measured high voltage rail.
A voltage rail compensation circuit as shown in
The voltage rail normalization in general provides an ability to reject base input disturbances.
A dead zone current loop as depicted in
The filtered signal goes through a dead zone function, which generates zero output within a specified region, referred to as its “dead zone.” If the input filtered signal is within the dead zone (greater than the lower limit and less than the upper limit), the output is zero. If the input filtered signal is greater than or equal to the upper limit, the output is the input minus the upper limit. If the input filtered signal is less than or equal to the lower limit, the output is the input minus the lower limit.
The output of the dead zone function can be considered the error that enters the PI compensator. The PI loop, which is depicted in
Although not shown within the FPGA architecture (see
Pulse width modulation can be performed with a high side field effect transistor (FET) that switches while a desired low side field effect transistor (FET) is closed.
Decimation filters preferably filter the sensed voltage and current signals, as well as the voltage rail. To prevent aliasing, 4th order decimation filters can be used. These filters are 2 second order section, IIR Butterworth filters with a cutoff frequency of 250 Hz and a sample rate of 96 kHz.
A schematic layout of a motor driver in accordance with the invention suitable for a resonant inertial actuator is shown in
In an embodiment the invention includes machine 61′. Machine 61′ includes resonant inertial actuator controller 65 and resonant inertial actuator 1. Resonant inertial actuator 1 has a resonant frequency. Resonant inertial actuator controller 65 electromagnetically drives resonant inertial actuator 1 at a near resonant frequency, with the near resonant frequency proximate the resonant frequency. Resonant inertial actuator controller 65 intermittently drives resonant inertial actuator 1 at an off-resonance frequency for separate intervals of time. The off-resonance frequency is distal from the resonant frequency, with resonant inertial actuator controller 65 monitoring a current and a voltage through resonant inertial actuator 1 over at least portions of the separate intervals of time. Resonant inertial actuator controller 65 calculates an operating parameter value of resonant inertial actuator 1 based on the monitored current and the monitored voltage within the separate time intervals, wherein the controller reduces the demanded force of resonant inertial actuator 1 in response to the calculated operating parameter value crossing a threshold value. Preferably resonant inertial actuator 1 is a cantilevered resonant inertial actuator, preferably with a sprung moving mass magnet part moving in an arc. Preferably the cantilevered resonant inertial actuator has adjacent composite flexures 52 with bonded elastomer end fret inhibiting shims 54 between the adjacent composite flexures. Preferably with the composite flexures providing for the sprung moving mass magnet part moving in the arc. Preferably resonant inertial actuator 1 operating parameter is at least one resonant inertial actuator operating parameter selected from the resonant inertial actuator operating parameter group including an actuator temperature, an actuator displacement, an actuator force, and an actuator power. Preferably resonant inertial actuator controller 65 electromagnetically drives resonant inertial actuator 1 at the near resonant frequency with a demanded force power, and the controller drives the resonant inertial actuator at the off-resonance frequency with a non-resonant frequency power less than the demanded force power.
It will be apparent to those skilled in the art that various modifications and variations can be made to the invention without departing from the spirit and scope of the invention. Thus, it is intended that the invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. It is intended that the scope of differing terms or phrases in the claims may be fulfilled by the same or different structure(s) or step(s).
Swanson, Douglas, Black, Paul, Badre-Alam, Askari, Pedersen, Douglas, Edeal, David
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